WO2017005697A1

WO2017005697A1 - Separating device and method for detecting a material accumulation in such a separating device

Info

Publication number: WO2017005697A1
Application number: PCT/EP2016/065719
Authority: WO
Inventors: Alfons LEUER; Heinz BREDEMEIER
Original assignee: Thyssenkrupp Industrial Solutions Ag; Thyssenkrupp Ag
Priority date: 2015-07-06
Filing date: 2016-07-04
Publication date: 2017-01-12
Also published as: EP3319731B1; DK3319731T3; EP3319731A1; DE102015110865A1

Abstract

A separate device comprising a housing (1), which forms an inlet (2) for a material mixture flow, a first outlet (3) for a first partial flow of the material mixture flow and a second outlet (5) for a second partial flow of the material mixture flow is characterised by a radar device (13) which is designed and arranged such that, by means of same, electromagnetic radiation can be transmitted through an interior space (8) delimited by the housing (1) in the direction of the first outlet (3) and is received again as reflected radiation. In this way, a material accumulation can be detected in the first outlet (3) and the separating device can be monitored with respect to an impending blockage.

Description

Separator and method for detecting accumulation of matter in such a separator

The invention relates to a separation device, for example in the form of a so-called cyclone. The invention further relates to a method for detecting a substance accumulation in such a separation device.

The essential parts of plants of the basic industry include separating devices, which may be formed for example in the form of static or dynamic classifiers or in the form of cyclones. While in classifiers primarily a classification of solids of different particle sizes occurs, cyclones usually serve to separate solids (especially small grain sizes, i.e. dust) from a gas flow. In plants of the basic industry, cyclones are used, for example, as separation and preheater cyclones.

For the separation of solids from a gas flow in a cyclone, the solid-gas mixture flow is set in rotation and the different inertias of the gas flow on the one hand and the solids on the other exploited to separate them. For this purpose, an outlet for the gas flow is arranged in such a way that the solids can not follow the gas flow into this outlet due to inertia. Rather, the solids fall downwards due to their separation from the mixture flow due to gravity and are discharged via a further outlet. In this case, the interior of a cyclone is usually designed such that it tapers in the direction of this outlet for the solids in order to ensure the most complete possible discharge.

Deposits of solids in the area of the associated outlet can lead to cyclone clogging and thus to a standstill of the plant integrating the cyclone. In order to avoid this, cyclones are regularly monitored, at least in plants of the basic industry, with regard to a possible blockage of the solids outlet. This can be done by means of a radiometric measuring device in which the housing of a cyclone in Area of the solids outlet is irradiated with gamma rays. In this case, a signal is output when the gamma radiation emitted by the gamma radiation source and received by a receiver falls below a defined limit value. The radioactive gamma radiation source required for such a radiometric measuring device leads to considerable safety requirements for the

Operation of the separation device.

Monitoring of a cyclone for a developing blockage in the area of the solids outlet can also be done by means of a pressure or differential pressure measurement. However, the measuring devices used for this purpose have so far been relatively maintenance-intensive. Furthermore, these measuring devices do not detect caking or braiding.

DE 10 2012 003 948 A1 discloses a fill level measuring system operating on the radar principle for a container receiving a medium, in the container wall of which a so-called microwave window which is at least partially transparent for microwave radiation is integrated. The level measuring system comprises a radiation source arranged outside the container, from which microwave radiation is emitted through the microwave window into the container in order to determine the level of the medium within the container.

Based on this prior art, the invention was the object of an advantageous way to detect a substance accumulation in one

Specify the outlet of a separator.

This object is achieved by means of a separating device according to the patent claim 1 and by means of a method according to the patent claim 10. Advantageous embodiments of the separating device according to the invention and preferred embodiments of the method according to the invention are objects of the other claims and will become apparent from the following description of the invention. A separating device with a housing which forms an inlet for a substance mixture flow, a first outlet for a first partial flow of the substance mixture flow and a second outlet for a second partial flow of the substance mixture flow, is characterized according to the invention by a radar device which is designed and arranged such that by means of this electromagnetic radiation can be emitted by an interior formed by the housing in the direction of the first outlet and can be received again as reflected radiation. Such a separation device advantageously makes it possible to detect a substance accumulation in the region of the first outlet. As a result, timely countermeasures can be taken by which a blockage of the separator in the region of the first outlet can be avoided.

A method according to the invention for detecting a substance pool in a first outlet of a separation device comprising an interior forming housing into which a mixture stream is introduced via an inlet and from which a first substream of the mixture flow via the first outlet and a second substream of the mixture flow via a second outlet is therefore characterized in that a collection of substances is detected and analyzed by evaluating electromagnetic radiation emitted by a radar device of the separation device in the direction of the first outlet and received back as reflected radiation. In the analysis, in particular, a comparison of a value of the reflected radiation with a reference value for the reflected radiation, which may have been determined, for example, in the new or empty state of the separation device, can be provided to determine from a difference of these values on a substance pool or a size value of to conclude such substance accumulation. In a preferred embodiment of the method according to the invention, it may also be provided that, by comparison with a reference measurement, not only the presence of a substance accumulation in the first outlet is detected, but also at least one layer thickness thereof Material collection, for example, an average layer thickness above the area detected by the electromagnetic radiation, is measured. If then several more staggered measurements are made, it can also be determined from a temporal change in the layer thickness. In this way, for example, an increase of the substance accumulation can be observed and a countermeasure can only be initiated when a critical value for this substance accumulation is reached. Furthermore, the very slow change of the measured Schichtdiche can point to a possible Wechte.

By a suitable analysis, for example by comparing a long-term detection with a short-term detection, the detected substance accumulation can also be in a static part, which may be formed by adhesions on the inside of the housing, and a dynamic part, which can be dissipated by the over the first outlet first sub-stream of the substance mixture stream can be formed, can be distinguished. In this way, only the leading to blockages attachments can be detected as accurately as possible. A significant advantage of the inventively provided use of a radar device for detecting a substance accumulation in an outlet of a separation device is in the case used, substantially harmless electromagnetic radiation, so that no additional safety requirements are required for the operation of the separator. Furthermore, suitable radar device are available inexpensively and they can be operated permanently even with low maintenance.

A radar device for a separating device according to the invention comprises at least one radiation source for the electromagnetic radiation and at least one receiver, by which at least part of the previously emitted electromagnetic radiation can be received again after reflection at a section of the inside of the housing. Furthermore, the radar device may also include an evaluation device, which serves to evaluate the received electromagnetic radiation and in this way enable the detection of a substance accumulation in the first outlet can. It can be provided that the radiation source (s) and / or the / the receiver and / or the evaluation device are integrated in a (same) structural unit. However, there is also the possibility of forming individual or all of these components separated from each other and possibly also spatially separated from each other to position, which, taking into account the concrete

Form of the reflection causing surfaces of the housing advantageous positioning of the radar device, in particular the transmitter and the receiver thereof may be useful.

The electromagnetic radiation may preferably have a frequency which is within a range of megahertz, gigahertz and / or terahertz

Includes frequencies.

Advantageously, the measure according to the invention is suitable for the detection of a substance accumulation in an outlet in a separation device which serves to separate (at least) one solid and (at least) one gas. Accordingly, the separating device according to the invention may comprise a housing having a

Inlet for a solid-gas mixture stream, a first outlet, which serves to discharge a separated from the mixture flow of solid (stream) s, and a second outlet, which serves to discharge the at least partially released from the solid gas stream. In particular, in such an embodiment of a separating device according to the invention can also be provided that the

Housing forms a starting from the inlet and / or the second outlet in the direction of the first outlet tapered interior, whereby a discharge of the separated from the mixture flow of solid (stream) s can be positively influenced. Likewise it can be provided that the inlet is oriented in such a way that the substance mixture flow or solid-gas

Mixture current decentralized with respect to a longitudinal axis of the rotationally symmetrical in at least a portion formed in the interior of the housing flows into this. Also, the first outlet and / or the second outlet are aligned such that the associated partial flow flows out of the housing in the direction of a longitudinal axis of the rotationally symmetrical interior of the housing. These constructive measures can in particular positively influence the separating effect of the separator.

Consequently, the separating device can be designed in particular in the form of a so-called cyclone, as it can furthermore preferably be used in a plant of the basic industry, in particular as a separator and / or preheater cyclone. In this case, it can furthermore preferably be provided that by means of the radar device or the electromagnetic radiation emitted and again received by the radar device, that (first) outlet of the separation device is monitored, which serves to remove the solid (current) separated from the gas flow.

In a preferred embodiment of the separation device according to the invention can be provided that the radar device is arranged partially or completely outside the interior of the housing. As a result, they can be protected from being exposed to the substance mixture stream or the partial streams or streams. Furthermore, it can be avoided that the radar device restricts the space available in the interior of the housing and / or influences the flow behavior of the substance mixture flow or one or more of the partial flows.

In order to ensure that it is possible to monitor the first outlet by means of a radar device arranged outside the interior of the housing, it is possible to form the housing completely from a material which is at least partially transparent to the specific electromagnetic radiation. However, this can adversely affect the cost and / or structural properties of the enclosure. Therefore, it can preferably be provided that the radar device is arranged in such a way that the emitted and reflected electromagnetic radiation passes through (at least) a wall section which is at least partially transparent for this electromagnetic radiation and subsequently designated as radiation-transparent. In this case, this wall section, for example, at least one of the specified in DE 10 2012 003 948 AI Materials, for example, from a glass or a ceramic (eg, meta-, quartz or Bohrsilikatglas) or from a plastic, such as polypropylene, polytetrafluoroethylene (PTFE) or Polietheretherketon (PEEK) may be formed. This may in particular make it possible to form the housing with the exception of this at least one wall section made of a metal, such as steel, whereby the separating device can be inexpensively provided with a stable housing.

It is also possible, however, that the reflected electromagnetic radiation emitted by the radar device and received back by the latter passes through an opening of the housing, so that a relatively expensive embodiment of at least one wall section of the housing made of a radiation-transparent material may be dispensed with.

In order to avoid accumulation of substances in the region of the transition of the radiation-transparent wall section into an adjacent (non-or at least less radiation-transparent) wall section of the housing, it can preferably be provided that this transition is formed without offset at least on the inside of the housing.

According to the invention, it can be preferred for the electromagnetic radiation emitted by the radar device to detect at least the first outlet (i.e., the outlet opening), whereby a substance accumulation within the first outlet can be detected. Alternatively or additionally, it can also be provided that an inner wall section of the housing bounding the first outlet is detected by the electromagnetic radiation emitted by the radar device, whereby a collection of substances, which may be present in particular as adhesions on this inner wall section, can be detected.

The indefinite articles ("a", "an", "an" and "an"), in particular in the patent claims and in the description generally describing the claims, are to be understood as such and not as numerical words. Corresponding Concrete components are thus to be understood as being present at least once and being able to be present multiple times.

The invention will be explained in more detail with reference to an embodiment shown in the drawing. In the drawing shows in a schematic representation:

Fig. 1: a separating device according to the invention in the form of a cyclone in one

Side view.

The illustrated in the drawing in the intended operating orientation, designed as a cyclone separator comprises a housing 1, which forms an inlet 2 for a substance mixture flow, specifically a solid-gas mixture stream 7, at the upper end of the housing 1 in tangential Orientation in a formed by the housing 1, rotationally symmetrical interior 8 opens. Furthermore, the housing forms a first outlet 3, which serves to discharge a first partial flow of the substance mixture flow, specifically the solids stream 4 separated from the solid-gas mixture flow. A likewise formed by the housing 1 second outlet 5 serves to discharge the liberated from the solid 17 gas flow. 6

The first outlet 3 and the second outlet 5 are aligned substantially coaxially with respect to a longitudinal axis 9 of the housing 1, the first outlet 3 formed by a jacket part 10 of the housing 1 being arranged below the second outlet 5 formed by an outlet tube 11. This outlet pipe 11 is integrated in a cover part 12 of the housing 1, wherein a portion of the outlet pipe 11 can extend into the interior 8 of the housing 1. As a result, the solid-gas mixture stream 7 that has entered the interior 8 of the housing 1 via the inlet 2 and subsequently into a swirling flow due to the tangential orientation of the inlet 2 and the rotationally symmetrical design of the interior 8 with respect to the longitudinal axis 9 is added to this longitudinal axis 9, realtiv must be strongly deflected in order to be discharged via the second outlet 5 again. This really strong Deflection can not be sufficiently followed by the solid (dust) to be separated from the fuel-gas mixture stream 7, as a result of which - supported by the force acting on the solid particles - is moved as a stream of solids 4 in the direction of the first outlet 3. A tapering, concretely frusto-conical configuration of the lower portion of the shell portion 10 of the housing 1 and thus also of the interior 8 thereby supports feeding the separated solids stream 4 to the first outlet 3. By means of the separation device can thus be a separation of the solid-gas mixture stream. 7 in the more or less dust-free gas stream 6, which flows as a result of the relatively low (compared to the first outlet 3) flow resistance through the second outlet 5 from the housing 1, and in the solids flow 4, via the first outlet 3 from the housing is discharged, be realized.

In order to detect and monitor a substance accumulation in the first outlet 3, a radar device 13 is provided according to the invention, which is arranged above the housing 1 and which emits electromagnetic waves 19 in the direction of the first outlet 3. In this case, these electromagnetic waves 19 pass through an optional radiation-transparent wall section 14 of the Deckensteiis

12 of the housing 1 therethrough. That of a radiation source 15 of the radar device

13 emitted electromagnetic waves 19 are more or less reflected by an inner wall portion of the housing 1 bounding the first outlet 3 and / or of the present in the region of this inner wall portion and the first outlet 3 solid 17, wherein at least a portion of this reflected electromagnetic radiation 19 through again the optional radiation-transparent wall portion 14 of the housing 1 passes and impinges on a receiver 16 of the radar device 13. By evaluating one or more values which characterize this re-received electromagnetic radiation and a comparison with one or more reference values, it is possible to deduce the amount of solid 17 present in the monitored area. This allows the detection of adhesions 18 of the solid 17 to the corresponding inner wall portion of the housing 1 and a measurement of a layer increase of these adhesions. All of this information can be used to early detection of impending blockage of the first outlet 3, the failure of a functional separation of the separator and possibly also to a standstill of a separator integrating system, such as a plant of the primary industry, to take appropriate countermeasures ,

List of reference numbers:

1st case

2nd inlet

3rd first outlet

4. Solid stream

5. second outlet

6. Gas flow

7. Solid-gas mixture stream

8. Interior

9. longitudinal axis of the housing

10. Jacket part of the housing

11. outlet pipe

12. Ceiling part of the housing

13. Radar device

14. Radiation-transparent wall section

15. Radiation source of the radar device

16. Receiver of the radar device

17. Solid

18. Adherence of the solid

19. electromagnetic waves

Claims

Claims:

A separation device comprising a housing (1) forming an inlet (2) for a mixture flow, a first outlet (3) for a first partial flow of the mixture flow and a second outlet (5) for a second partial flow of the mixture flow, characterized by a Radar device (13), which is designed and arranged such that by means of this electromagnetic radiation through one of the housing (1) limited interior (8) in the direction of the first outlet (3) emanating and as a reflected radiation is receivable again.

2. Separating device according to claim 1, characterized in that the radar device (13) partially or completely outside the interior (8) of the housing (1) is arranged.

3. Separating device according to claim 2, characterized in that the radar device (13) is arranged such that the electromagnetic radiation passes through a radiation-transparent wall portion (14).

4. Separating device according to claim 3, characterized in that the radiation-transparent wall section (14) on the inside passes without offset in an adjacent wall portion of the housing (1).

5. Separating device according to one of the preceding claims, characterized in that the housing (1) starting from the inlet (2) and / or the second outlet (5) in the direction of the first outlet (3) in at least one section tapered interior (8) trains.

6. Separating device according to one of the preceding claims, characterized in that the of the radar device (13) emitted electromagnetic radiation detects the first outlet (3) and / or a first outlet (3) defining the inner wall portion of the housing (1).

7. Separating device according to one of the preceding claims, characterized in that the inlet (2) is oriented such that the substance mixture flow decentralized with respect to a longitudinal axis (9) of at least a portion in a rotationally symmetrical gebidleten interior (8) of the housing (1) in this flows.

8. Separating device according to one of the preceding claims, characterized in that the first outlet (3) and / or the second outlet (5) are aligned such that the respective partial flow in the direction of a longitudinal axis (9) of the interior (8) of the housing (1) flows out of this.

9. Use of a separating device according to one of the preceding claims for the separation of a solid and a gas.

10. A method for detecting a substance accumulation in a first outlet (3) of a separation device comprising an interior (8) limiting housing (1) into which via an inlet (2) introduced a substance mixture stream and from which a first substream of the substance mixture stream via the first outlet (3) and a second substream of the substance mixture stream via a second outlet (5), characterized in that a substance accumulation by an evaluation of electromagnetic radiation from a radar device (13) of the separation device in the direction of the first outlet (3) was sent out and received again after reflection, is detected.

11. The method according to claim 10, characterized in that a layer thickness of the substance accumulation is measured by a comparison with a reference measurement.

12. The method according to claim 11, characterized in that a temporal change in the layer thickness is determined based on a plurality of time-offset measurements.